Your search keyword '"Moon Bo-Hyun"' showing total 3 results

1. A Disease-Associated Microbial and Metabolomics State in Relatives of Pediatric Inflammatory Bowel Disease Patients.

Author

Jacobs, Jonathan P, Jacobs, Jonathan P, Goudarzi, Maryam, Singh, Namita, Tong, Maomeng, McHardy, Ian H, Ruegger, Paul, Asadourian, Miro, Moon, Bo-Hyun, Ayson, Allyson, Borneman, James, McGovern, Dermot PB, Fornace, Albert J, Braun, Jonathan, Dubinsky, Marla, Jacobs, Jonathan P, Jacobs, Jonathan P, Goudarzi, Maryam, Singh, Namita, Tong, Maomeng, McHardy, Ian H, Ruegger, Paul, Asadourian, Miro, Moon, Bo-Hyun, Ayson, Allyson, Borneman, James, McGovern, Dermot PB, Fornace, Albert J, Braun, Jonathan, and Dubinsky, Marla

Abstract

Background & aimsMicrobes may increase susceptibility to inflammatory bowel disease (IBD) by producing bioactive metabolites that affect immune activity and epithelial function. We undertook a family based study to identify microbial and metabolic features of IBD that may represent a predisease risk state when found in healthy first-degree relatives.MethodsTwenty-one families with pediatric IBD were recruited, comprising 26 Crohn's disease patients in clinical remission, 10 ulcerative colitis patients in clinical remission, and 54 healthy siblings/parents. Fecal samples were collected for 16S ribosomal RNA gene sequencing, untargeted liquid chromatography-mass spectrometry metabolomics, and calprotectin measurement. Individuals were grouped into microbial and metabolomics states using Dirichlet multinomial models. Multivariate models were used to identify microbes and metabolites associated with these states.ResultsIndividuals were classified into 2 microbial community types. One was associated with IBD but irrespective of disease status, had lower microbial diversity, and characteristic shifts in microbial composition including increased Enterobacteriaceae, consistent with dysbiosis. This microbial community type was associated similarly with IBD and reduced microbial diversity in an independent pediatric cohort. Individuals also clustered bioinformatically into 2 subsets with shared fecal metabolomics signatures. One metabotype was associated with IBD and was characterized by increased bile acids, taurine, and tryptophan. The IBD-associated microbial and metabolomics states were highly correlated, suggesting that they represented an integrated ecosystem. Healthy relatives with the IBD-associated microbial community type had an increased incidence of elevated fecal calprotectin.ConclusionsHealthy first-degree relatives can have dysbiosis associated with an altered intestinal metabolome that may signify a predisease microbial susceptibility state or subclinical

Published

2016

2. A Disease-Associated Microbial and Metabolomics State in Relatives of Pediatric Inflammatory Bowel Disease Patients.

Author

Jacobs, Jonathan P, Jacobs, Jonathan P, Goudarzi, Maryam, Singh, Namita, Tong, Maomeng, McHardy, Ian H, Ruegger, Paul, Asadourian, Miro, Moon, Bo-Hyun, Ayson, Allyson, Borneman, James, McGovern, Dermot PB, Fornace, Albert J, Braun, Jonathan, Dubinsky, Marla, Jacobs, Jonathan P, Jacobs, Jonathan P, Goudarzi, Maryam, Singh, Namita, Tong, Maomeng, McHardy, Ian H, Ruegger, Paul, Asadourian, Miro, Moon, Bo-Hyun, Ayson, Allyson, Borneman, James, McGovern, Dermot PB, Fornace, Albert J, Braun, Jonathan, and Dubinsky, Marla

Abstract

Background & aimsMicrobes may increase susceptibility to inflammatory bowel disease (IBD) by producing bioactive metabolites that affect immune activity and epithelial function. We undertook a family based study to identify microbial and metabolic features of IBD that may represent a predisease risk state when found in healthy first-degree relatives.MethodsTwenty-one families with pediatric IBD were recruited, comprising 26 Crohn's disease patients in clinical remission, 10 ulcerative colitis patients in clinical remission, and 54 healthy siblings/parents. Fecal samples were collected for 16S ribosomal RNA gene sequencing, untargeted liquid chromatography-mass spectrometry metabolomics, and calprotectin measurement. Individuals were grouped into microbial and metabolomics states using Dirichlet multinomial models. Multivariate models were used to identify microbes and metabolites associated with these states.ResultsIndividuals were classified into 2 microbial community types. One was associated with IBD but irrespective of disease status, had lower microbial diversity, and characteristic shifts in microbial composition including increased Enterobacteriaceae, consistent with dysbiosis. This microbial community type was associated similarly with IBD and reduced microbial diversity in an independent pediatric cohort. Individuals also clustered bioinformatically into 2 subsets with shared fecal metabolomics signatures. One metabotype was associated with IBD and was characterized by increased bile acids, taurine, and tryptophan. The IBD-associated microbial and metabolomics states were highly correlated, suggesting that they represented an integrated ecosystem. Healthy relatives with the IBD-associated microbial community type had an increased incidence of elevated fecal calprotectin.ConclusionsHealthy first-degree relatives can have dysbiosis associated with an altered intestinal metabolome that may signify a predisease microbial susceptibility state or subclinical

Published

2016

3. An Integrated Multi-Omic Approach to Assess Radiation Injury on the Host-Microbiome Axis.

Author

Goudarzi, Maryam, Goudarzi, Maryam, Mak, Tytus D, Jacobs, Jonathan P, Moon, Bo-Hyun, Strawn, Steven J, Braun, Jonathan, Brenner, David J, Fornace, Albert J, Li, Heng-Hong, Goudarzi, Maryam, Goudarzi, Maryam, Mak, Tytus D, Jacobs, Jonathan P, Moon, Bo-Hyun, Strawn, Steven J, Braun, Jonathan, Brenner, David J, Fornace, Albert J, and Li, Heng-Hong

Abstract

Medical responders to radiological and nuclear disasters currently lack sufficient high-throughput and minimally invasive biodosimetry tools to assess exposure and injury in the affected populations. For this reason, we have focused on developing robust radiation exposure biomarkers in easily accessible biofluids such as urine, serum and feces. While we have previously reported on urine and serum biomarkers, here we assessed perturbations in the fecal metabolome resulting from exposure to external X radiation in vivo. The gastrointestinal (GI) system is of particular importance in radiation biodosimetry due to its constant cell renewal and sensitivity to radiation-induced injury. While the clinical GI symptoms such as pain, bloating, nausea, vomiting and diarrhea are manifested after radiation exposure, no reliable bioindicator has been identified for radiation-induced gastrointestinal injuries. To this end, we focused on determining a fecal metabolomic signature in X-ray irradiated mice. There is overwhelming evidence that the gut microbiota play an essential role in gut homeostasis and overall health. Because the fecal metabolome is tightly correlated with the composition and diversity of the microorganism in the gut, we also performed fecal 16S rRNA sequencing analysis to determine the changes in the microbial composition postirradiation. We used in-house bioinformatics tools to integrate the 16S rRNA sequencing and metabolomic data, and to elucidate the gut integrated ecosystem and its deviations from a stable host-microbiome state that result from irradiation. The 16S rRNA sequencing results indicated that radiation caused remarkable alterations of the microbiome in feces at the family level. Increased abundance of common members of Lactobacillaceae and Staphylococcaceae families, and decreased abundances of Lachnospiraceae, Ruminococcaceae and Clostridiaceae families were found after 5 and 12 Gy irradiation. The metabolomic data revealed statistically signific

Published

2016